Tunable Topological Phase Transitions in a Piezoelectric Janus Monolayer

TL;DR

This paper identifies strain-tunable quantum spin Hall insulators in monolayer MAlGaTe4, demonstrating their potential for controllable topological phase transitions and applications in low-power topological devices.

Contribution

It introduces a new class of piezoelectric monolayers that exhibit strain-induced topological phase transitions, including metal-insulator and topological phase changes, expanding the material platform for topological electronics.

Findings

Ca and Sr compounds are QSH insulators at zero strain.

Mg compound transitions from normal insulator to QSH under strain.

MgAlGaTe4 exhibits both metal-insulator and topological phase transitions.

Abstract

Quantum Spin Hall (QSH) insulators represent a quintessential example of a topological phase of matter, characterized by a conducting edge mode within a bulk energy gap. The pursuit of a tunable QSH state stands as a pivotal objective in the development of QSH-based topological devices. In this study, we employ first-principles calculations to identify three strain-tunable QSH insulators based on monolayer MAlGaTe4 (where M represents Mg, Ca, or Sr). These monolayers exhibit dynamic stability, with no imaginary modes detected in their phonon dispersion. Additionally, they possess piezoelectric properties, rendering them amenable to strain-induced tuning. While MgAlGaTe4 is a normal insulator under zero strain, it transitions into the QSH phase when subjected to external strain. Conversely, CaAlGaTe4 and SrAlGaTe4 already exhibit the QSH phase at zero strain. Intriguingly, upon the application of biaxial strain, these two compounds undergo phase transitions, encompassing metallic (M), normal/trivial insulator (NI), and topological insulator (TI) phases, thereby illustrating their strain-tunable electronic and topological properties. (Ca, Sr)AlGaTe4, in particular, undergo M-TI/TI-M transitions under applied strain, while MgAlGaTe4 additionally experiences an M-NI/NI-M transition, signifying it as a material featuring a metal-insulator transition (MIT). Remarkably, the observation of metal-trivial insulator-topological insulator transitions in MgAlGaTe4 introduces it as a unique material platform in which both MIT and topological phase transitions can be controlled through the same physical parameter. Our study thus introduces a novel material platform distinguished by highly strain-tunable electronic and topological properties, offering promising prospects for the development of next-generation, low-power topological devices.